ee 350 / ece 490 analog communication systems
DESCRIPTION
EE 350 / ECE 490 Analog Communication Systems. Ch. 11 – Network Communications Telephone Systems. Figure 11-1 Telephone representation. Figure 11-2 Touch-tone dialing. Figure 11-3 Telephone system block diagram. Figure 11-4 Two- to four-wire conversion. - PowerPoint PPT PresentationTRANSCRIPT
EE 350 / ECE 490ANALOG COMMUNICATION SYSTEMS
Ch. 11 – Network Communications Telephone Systems
2/23/2010R. Munden - Fairfield University 1
FIGURE 11-1 TELEPHONE REPRESENTATION.
FIGURE 11-2 TOUCH-TONE DIALING.
FIGURE 11-3 TELEPHONE SYSTEM BLOCK DIAGRAM.
FIGURE 11-4 TWO- TO FOUR-WIRE CONVERSION.
FIGURE 11-5 ATTENUATION FOR 12,000 FT OF 26-GAUGE WIRE.
FIGURE 11-6 ATTENUATION DISTORTION LIMIT FOR 3002 CHANNEL.
FIGURE 11-7 DELAY EQUALIZATION.
FIGURE 11-8 SS7 LEVELS.
FIGURE 11-9 AN EXAMPLE OF CAPTURED TELEPHONE SIGNALING MESSAGES AS DISPLAYED USING A TEKTRONIX K15 PROTOCOL ANALYZER.
FIGURE 11-10 CONFIGURATION ON THE PROTOCOL ANALYZER SET TO DISPLAY ONLY THE “TEMPORARY FAILURE MESSAGES.
EE 350 / ECE 490ANALOG COMMUNICATION SYSTEMS
Ch. 12 – Transmission Lines
2/23/2010R. Munden - Fairfield University 12
OBJECTIVES Describe the operational characteristics of twisted-pair cable
and its testing considerations Describe the physical characteristics of standard
transmission lines and calculate Z0 Calculate the velocity of propagation and the delay factor Analyze wave propagation and reflection for various line
configurations Describe how standing waves are produced and calculate
the standing wave ratio Use the Smith chart to find input impedance and match
loads to a line with matching sections and single-stub tuners Explain the use of line sections to simulate discrete circuitry Troubleshoot the location of a line break using TDR concepts
12-1 INTRODUCTION A transmission line is the conductive
connections between system elements that carry signal power.
At RF you can’t simply consider “wires” to be short circuits
Energy may also be reflected back
12-2 TYPES OF TRANSMISSION LINES Two-Wire Open Line Twisted Pair Unshielded Twisted Pair (UTP) Shielded Pair Coaxial Lines Balanced/Unbalanced Lines
TWO-WIRE OPEN LINE
FIGURE 12-1 PARALLEL TWO-WIRE LINE. FIGURE 12-2 TWO-WIRE RIBBON-TYPE LINES.
Used antenna and transmitter or receiver
UNSHIELDED TWISTED PAIR (UTP)
FIGURE 12-3 TWISTED PAIR.
FIGURE 12-4 A GRAPHICAL ILLUSTRATION OF NEAR-END CROSSTALK.
• UTP very common in LANs, now CAT6 and 5e capable of 1000 Mbps for 100 m.
• 4 color-coded twisted pairs w/ RJ-45 connector
• Achieving high data rates depends on low attenuation and near-end crosstalk (NEXT)
• Delay skew (from uneven lengths) is also important in high speed communications
• Return loss is related to signal power reflection due to impedance changes throughout the cable.
SHIELDED PAIR
FIGURE 12-5 SHIELDED PAIR.
• Conductors are balanced to ground due to shielding cable• Outside interference is minimized • Cross-talk is minimized
COAXIAL
FIGURE 12-6 RIGID; AIR COAXIAL: CABLE WITH WASHER INSULATOR.
FIGURE 12-7 FLEXIBLE COAXIAL. MOST COMMON VERSION OF COAX; MORE LOSSY, BUT EASIER TO MAKE AND USE
Most common form of transmission line
COAX CONNECTORS
BALANCED/UNBALANCED LINES
FIGURE 12-8 BALANCED/UNBALANCED CONVERSION. USES A CENTER-TAPPED TRANSFORMER AS A BALUN.
180° out of phase for CMR
12-3 ELECTRICAL CHARACTERISTICS OF TRANSMISSION LINES Generator (Input) is nearest source Load (Receiving) end is nearest load
No line is perfect, there are always electrons moving through the dielectric.
In a uniform line, one section can represent the entire line
TWO-WIRE TRANSMISSION LINE
Figure 12-9 Equivalent circuit for a two-wire transmission line
CHARACTERISTIC IMPEDANCE
Fig 12-10 Simplified circuit terminated with characteristic impedance
CL
fCfLZZZ
nn
ZZZZ
ZZZZ
ZZZZZZZZZZZZZZZZZ
ZZZZZZZZZZ
ZZZZZZZZZ
ZZZZZZZZ
2
12
sections withReplacing2
2/22Simplify
2)2/2()2/(2)2/2(2)2/(
2)2/2()2/()2/(
)2/(2
)2/(])2/[(
2
Derivation Impedance sticCharacteri
210
21
212
0
2121
20
2021012
1212
00102
012
2021012
1210
012
201210
012
01210
DETERMINING CHARACTERISTIC IMPEDANCE For Two-wire lines:
For Coax lines:insulator of constant dielectric
conductor of diameter dcenter)-to-(center wiresbetween spacing
2log276100
D
dDZ
insulator of constant dielectric conductor inner of diameter outer dconductor outer of diameter inner
log138100
D
dDZ
Insulator ε
Air 1Polyethylene 2.3Teflon 2.1Polyethylene Foam
1.6
TRANSMISSION LINE LOSSES
Copper Losses – I2R goes up at high frequency due to skin effect
Dielectric Losses – increases with voltage and frequency. Best with air, or low dielectric constant.
Induction or Radiation Losses – minimized with grounded coax and proper termination
FIGURE 12-11 LINE ATTENUATION CHARACTERISTICS.
12-4 PROPAGATION OF DC VOLTAGE DOWN A LINE Physical Explanation of Propagation Velocity of Propagation Delay Line Wavelength
DC PROPAGATION
FIGURE 12-12 DC VOLTAGE APPLIED TO A TRANSMISSION LINE.
Look at it as sequential charging of capacitors through the inductors
VELOCITY OF PROPAGATION
rf
p
v
LCdV
LCt
1
fV
fc p
Wavelength in a line:
12-5 NONRESONANT LINE Traveling DC Waves Traveling AC Waves
Definition of a line terminated in its characteristic impedance
TRAVELING DC WAVES
FIGURE 12-14 CHARGED NONRESONANT LINE.
TRAVELING AC WAVESAC signals move as a wavefront
The instantaneous voltage along the points of the line reproduce the signal generator
All the power is absorbed by the termination resistor
12-6 RESONANT TRANSMISSION LINE DC Applied to an Open-Circuited Line Incident and Reflected Waves DC Applied to a Short-Circuited Line Standing Waves: Open Line Standing Waves: Shorted Line
DC ON AN OPEN CIRCUIT LINE
FIGURE 12-16 OPEN-ENDED TRANSMISSION LINE.
Voltage propagates to the end charging C3, then since no current can flow the charge in the inductors must dissipate into the capacitors, causes 2x voltage to be reflected back to the input
INCIDENT AND REFLECTED WAVES
FIGURE 12-17 DIRECT CURRENT APPLIED TO AN OPEN-CIRCUITED LINE.
In DC at 1us the load “sees” DC, but the source doesn’t “see” DC until 1us
Reflected V in phaseReflected I out of phase
Reflected V out of phaseReflected I in phase
DC APPLIED TO A SHORT-CIRCUITED LINE
FIGURE 12-18 DIRECT CURRENT APPLIED TO A SHORT-CIRCUITED LINE.
STANDING WAVES
When a line is not terminated appropriately a standing wave can develop, points in the line where the voltage and current never change
STANDING WAVES
FIGURE 12-20 CONVENTIONAL PICTURE OF STANDING—WAVES OPEN LINE.
FIGURE 12-21 STANDING WAVES OF VOLTAGE AND CURRENT.
FIGURE 12-22 DIAGRAM FOR EXAMPLE 12-6.
12-7 STANDING WAVE RATIO Reflection Coefficient:
Quarter-Wavelength Transformer Electrical Length
11
min
max
0
0
EEVSWR
ZZZZ
EE
L
L
i
r
EFFECTS OF MISMATCH The full generator power does not reach the
load The cable dielectric may break down as a
result of high-value standing waves of voltage (voltage nodes).
The existence of reflections (and rereflections) increases the power loss in the form of I2R heating, especially at the high-value standing waves of current (current nodes)
Noise problems are increased by mismatches “Ghost” signals can be created
0
0 or ZR
RZVSWR L
L
QUARTER-WAVELENGTH TRANSFORMER
FIGURE 12-23 /4 MATCHING SECTION FOR EXAMPLE 12-7.
LRZZ 00'
ELECTRICAL LENGTH
FIGURE 12-24 EFFECT OF LINE ELECTRICAL LENGTH.
Transmission line effects are only important when the lines are electrically long. For telephone 300Hz signals λ=621 miles, so it doesn’t really matter. For 10 GHz signals λ=3 cm.
12-8 THE SMITH CHART Transmission Line Impedance Smith Chart Introduction Using the Smith Chart Corrections for Transmission Loss Matching Using the Smith Chart Stub Tuners
SMITH CHART
FIGURE 12-24 SMITH CHART.
sjZZsjZZZZ
L
LS
tantan
0
00
Line impedance at a point
FIGURE 12-26 SMITH CHART FOR EXAMPLE 12-8.
FIGURE 12-27 SMITH CHART FOR EXAMPLE 12-9.
FIGURE 12-28 STUB TUNERS.
FIGURE 12-29 SMITH CHART FOR EXAMPLE 12-10.
12-9 TRANSMISSION LINE APPLICATIONS Discrete Circuit Simulation Baluns Transmission Lines as Filters Slotted Lines Time-Domain Reflectometery
FIGURE 12-30 TRANSMISSION LINE SECTION EQUIVALENCY.
FIGURE 12-31 BALUNS.
FIGURE 12-32 QUARTER-WAVE FILTERS.
FIGURE 12-33 TIME-DOMAIN REFLECTOMETRY.
FIGURE 12-33 (CONTINUED) TIME-DOMAIN REFLECTOMETRY.
12-10 TROUBLESHOOTING Common Applications Losses on Transmission Lines Interference on Transmission Lines Cable Testing Television Antenna Line Repair
FIGURE 12-34 HEAT RADIATION AND LEAKAGE LOSSES.
12-11 TROUBLESHOOTING W/ MULTISIM
FIGURE 12-35 AN EXAMPLE OF USING THE MULTISIM NETWORK ANALYZER TO ANALYZE A 50-Ω RESISTOR.
FIGURE 12-36 THE SMITH CHART FOR THE TEST OF THE 50- Ω RESISTOR.
FIGURE 12-37 THE SMITH CHART RESULT FOR THE SIMPLE RC NETWORK.
FIGURE 12-38 THE SMITH CHART RESULT FOR THE SIMPLE RL NETWORK.